Origin of strong solid solution strengthening in the CrCoNi-W medium entropy alloy

[Display omitted] •Alloying strengthening effect can be much more significant in multi-principle element solid solutions.•Dislocation behaviors and structure is highly sensitive to W addition in multi- principle element solid solutions.•Adding small amount of W can bring strong change in elements co...

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Bibliographic Details
Published in:Journal of materials science & technology 2021-05, Vol.73, p.101-107
Main Authors: Chen, Yujie, Fang, Yan, Fu, Xiaoqian, Lu, Yiping, Chen, Sijing, Bei, Hongbin, Yu, Qian
Format: Article
Language:English
Subjects:
Alloying effect
Chemical distribution heterogeneity
In situ observation
Medium entropy alloy
Solid solution strengthening mechanism
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Summary:[Display omitted] •Alloying strengthening effect can be much more significant in multi-principle element solid solutions.•Dislocation behaviors and structure is highly sensitive to W addition in multi- principle element solid solutions.•Adding small amount of W can bring strong change in elements concentration wave in HEAs.•The effect of adding the same amount of W to single element metal is negligible. Solid solution strengthening is one of the most conventional strategies for optimizing alloys strength, while the corresponding mechanisms can be more complicated than we traditionally thought specifically as heterogeneity of microstructure is involved. In this work, by comparing the change of chemical distribution, dislocation behaviors and mechanical properties after doping equivalent amount of tungsten (W) atoms in CrCoNi alloy and pure Ni, respectively, it is found that the alloying element W in CrCoNi alloy resulted in much stronger strengthening effect due to the significant increase of heterogeneity in chemical distribution after doping trace amount of W. The large atomic scale concentration fluctuation of all elements in CrCoNi-3W causes dislocation motion via strong nanoscale segment detrapping and severe dislocation pile up which is not the case in Ni-3W. The results revealed the high sensitivity of elements distribution in multi-principle element alloys to composition and the significant consequent influence in tuning the mechanical properties, giving insight for complex alloy design.
ISSN:1005-0302
1941-1162
DOI:10.1016/j.jmst.2020.08.058